Reflectivity measurement apparatus and method of measuring reflectivity therefor

1 . A method of measuring reflectivity in a heating appliance comprising a substrate for receiving an item of cookware, the method comprising: emitting a time-varying electromagnetic signal from a first side of the substrate, a portion of the time-varying electromagnetic signal propagating through the substrate; receiving electromagnetic radiation at the first side of the substrate, the received electromagnetic radiation comprising a background ambient component of electromagnetic radiation received and a reflected component of the time-varying electromagnetic signal reflected by the substrate; applying a gain factor to translate the received electromagnetic radiation to a receive electrical signal, the gain factor applied being responsive to the background ambient component of electromagnetic radiation received; identifying an offset signal component from the receive electrical signal, the offset signal component arising from the background ambient component of electromagnetic radiation received; estimating the gain factor from the offset signal component using a characterisation of the offset signal component; and calculating the reflectivity using the receive electrical signal and the estimated gain factor. 2 . The method according to claim 1 , wherein calculating the reflectivity further comprises: identifying the reflected component of the time-varying electromagnetic signal; and compensating the identified reflected component of the time-varying electromagnetic signal using the estimated gain factor. 3 . The method according to claim 1 , wherein calculating the reflectivity further comprises: attenuate the identified offset signal component from the receive electrical signal. 4 . The method according to claim 1 , further comprising: identifying the reflected component of the time-varying electromagnetic signal; and using the estimated gain factor to calculate a parameter of emission of the time-varying electromagnetic signal, the calculated parameter of emission of the time-varying electromagnetic signal compensating the identified reflected component of the time-varying electromagnetic signal. 5 . The method according to claim 1 , further comprising: analysing the receive electrical signal and repeatedly extracting the offset signal component from the receive electrical signal. 6 . A method of measuring reflectivity of a substrate of an inductive cooking appliance, the method comprising: measuring reflectivity of the substrate in the presence of the background ambient component of electromagnetic radiation according to claim 1 . 7 . A method of measuring the reflectivity of an item of cookware disposed on a substrate of an inductive cooking appliance, the method comprising: measuring reflectivity of the substrate according to claim 6 ; placing the item of cookware on the substrate; and emitting another time-varying electromagnetic signal from the first side of the substrate, a portion of the another time-varying electromagnetic signal propagating through the substrate; receiving further electromagnetic radiation at the first side of the substrate, the further received electromagnetic radiation comprising a first reflected component of the time-varying electromagnetic signal reflected by the substrate and a second reflected component of the time-varying electromagnetic signal reflected by the item of cookware; translating the further received electromagnetic radiation to another receive electrical signal; and calculating the reflectivity additionally using the another receive electrical signal. 8 . The method according to claim 7 , further comprising: applying the gain factor to translate the further received electromagnetic radiation to another receive electrical signal, the gain factor applied being responsive to the background ambient component of electromagnetic radiation received. 9 . The method according to claim 7 , wherein the time-varying electromagnetic signal and the another time-varying electromagnetic signal share a common time-varying electrical drive signal; and calculating the reflectivity further comprises: calculating a fraction of the time-varying electromagnetic signal that is received as the second reflected component of the time-varying electromagnetic signal. 10 . The method according to claim 9 , wherein calculating the fraction comprises using the gain factor, the receive electrical signal, and the another receive electrical signal, and a predetermined reflectivity value of the substrate. 11 . The method according to claim 10 , wherein the reflectivity is calculated using the following equation: ( A m ⁢ eas ⁢ 2 - A meas ⁢ 1 ) × R s A meas ⁢ 1 where A meas2 is an amplitude of the another receive electrical signal, A meas1 is an amplitude of the receive electrical signal compensated using the estimated gain factor, and R S is the predetermined reflectivity value of the substrate. 12 . A method of heating cookware inductively, the method comprising: measuring reflectivity of an item of cookware according to claim 7 ; receiving a demand for inductive heating after measuring the reflectivity of the item of cookware; and generating an inductive electromagnetic heating signal in response to the demand for inductive heating. 13 . A reflectivity measurement apparatus comprising: an electromagnetic illumination circuit configured to emit a time-varying electromagnetic signal from a first side of a substrate of a heating appliance, the time-varying electromagnetic signal propagating, when in use, through the substrate; a photodetector circuit configured to receive electromagnetic radiation at the first side of the substrate, the received electromagnetic radiation comprising a background ambient component of electromagnetic radiation and a reflected component of the time-varying electromagnetic signal reflected by the substrate; the photodetector circuit is configured to apply a gain factor to translate the received electromagnetic radiation to a receive electrical signal, the gain factor applied being responsive to the background ambient component of electromagnetic radiation received; a signal processing unit configured to identify an offset signal component from the receive electrical signal, the offset signal component arising from the background ambient component of the received electromagnetic radiation; wherein the signal processing unit is configured to estimate the gain factor from the offset signal component using a characterisation of the offset signal component; and the signal processing unit is configured to calculate the reflectivity using the receive electrical signal and the estimated gain factor. 14 . An inductive hea